JP2018198394A - Wireless gateway system and communication method thereof - Google Patents

Abstract

The present invention provides a wireless gateway system and a communication method therefor that are low in cost, reduce work burden for installation, and suppress deterioration in performance of wireless communication with wireless field devices. A power supply device converts a voltage from an external power source into a predetermined internal voltage, supplies the internal voltage to a gateway device, and performs first wired communication between an external controller and the gateway device. A wired signal corresponding to a protocol is transmitted, and the gateway device operates using the internal voltage supplied from the power supply device as a power source, and the wireless signal corresponding to the wireless communication protocol received from the wireless field device is wired. The signal is converted into a signal and transmitted to the power supply device. [Selection] Figure 1

Description

  The present invention relates to a wireless gateway system and a communication method thereof.

  Patent Literature 1 below describes a wireless gateway device having a so-called gateway function that converts a wireless signal received from an antenna from a wireless field device into a wired protocol and transfers it to an external controller. This wireless gateway device can execute a gateway function by being driven by electric power supplied from an external power source.

By the way, the following (1) and (2) can be considered as the installation location of the wireless gateway device.
(1) The wireless gateway device may be preferably installed at a high place including an antenna in order to obtain good communication characteristics with the field wireless device.
(2) It may be preferable to install the wireless gateway device in a low place together with an external controller in consideration of maintainability, and to install only the antenna in a high place.

JP2013-152538A

  Here, since the wireless gateway apparatus has a power supply circuit and needs to comply with explosion-proof requirements for an industrial plant, it is generally large in size and heavy. For this reason, in order to fix such a wireless gateway device at a high place as in the above installation method (1), an expensive member such as a heavy clasp is required. Moreover, the work burden for installing in a high place is large.

  On the other hand, if the cable is extended in order to install only the antenna at a high place as in the above installation method (2), the high-frequency radio signal flowing through the cable deteriorates, and the antenna and the field wireless device are not connected. Wireless communication performance is degraded.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a wireless gateway system that is low in cost, reduces work load for installation, and suppresses deterioration in performance of wireless communication with wireless field devices, and It is to provide a communication method.

  One embodiment of the present invention is a wireless gateway system including a gateway device having a gateway function and including an antenna that wirelessly communicates with a wireless field device, and a power supply device configured separately from the gateway device. The power supply device converts a voltage from an external power source into a predetermined internal voltage, supplies the internal voltage to the gateway device, and a first wire between the external controller and the gateway device. A wired signal corresponding to a communication protocol is transmitted, the gateway device operates using the internal voltage supplied from the power supply device as a power source, and a wireless signal corresponding to a wireless communication protocol received from the wireless field device is transmitted to the gateway device. A wireless gate, wherein the wireless gate is converted into a wired signal and transmitted to the power supply device Is Eishisutemu.

  One aspect of the present invention is the above-described wireless gateway system, wherein a cable for supplying an internal voltage is wired between the power supply device and the gateway device, and the power supply device includes: It further includes an overcurrent protection circuit that stops the supply of the internal voltage when it is detected that an overcurrent flows through the cable.

  One aspect of the present invention is the above-described wireless gateway system, in which the power supply device can bidirectionally transmit the wired signal while electrically insulating the external controller and the gateway device. An insulation circuit is further provided.

  One aspect of the present invention is the above-described wireless gateway system, wherein the gateway device converts the wired signal received from the power supply device into the wireless signal and transmits the wireless signal to the wireless field device.

  One aspect of the present invention is the above-described wireless gateway system, wherein the power supply device converts the wired signal received from the gateway device into a second wired communication protocol different from the first wired communication protocol. And a signal converter for transmitting to the external controller.

  One aspect of the present invention is a communication method of a wireless gateway system including a gateway device having a gateway function and wirelessly communicating with a wireless field device, and a power supply device configured separately from the gateway device. Converting a voltage from an external power source into a predetermined internal voltage and supplying the internal voltage from the power supply device to the gateway device; and a wireless signal corresponding to a wireless communication protocol received from the wireless field device Is converted into a wired signal corresponding to the first wired communication protocol and transmitted from the gateway device to the power supply device, and the wired signal transmitted from the gateway device to the power supply device is converted to an external controller. And transmitting to the wireless gateway system, Is a non-communication methods.

  As described above, according to the present invention, it is possible to reduce the cost, the work load for installation, and the performance of wireless communication with a field wireless device.

It is a figure which shows an example of schematic structure of the radio | wireless communications system A in which the radio | wireless gateway system which concerns on 1st Embodiment is used. It is a figure explaining operation | movement in the case of transmitting the measured value which the wireless field device 1 which concerns on 1st Embodiment measured to the external controller 5. FIG. It is a figure explaining the operation | movement in the case of controlling the wireless field device 1 which concerns on 1st Embodiment. It is a figure which shows an example of schematic structure of the radio | wireless communications system B in which the radio | wireless gateway system which concerns on 2nd Embodiment is used. It is a figure explaining operation | movement in the case of transmitting the measured value which the wireless field device 1 which concerns on 2nd Embodiment measured to the external controller 5. FIG.

  Hereinafter, a wireless gateway system according to an embodiment of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a diagram illustrating an example of a schematic configuration of a wireless communication system A in which the wireless gateway system according to the first embodiment is used.

  The wireless communication system A is constructed in, for example, a plant, a factory, or the like (hereinafter simply referred to as “plant” when collectively referred to). Here, as the above plant, in addition to industrial plants such as chemicals, plants that manage and control wells such as gas fields and oil fields and their surroundings, plants that manage and control power generation such as hydropower, thermal power, and nuclear power, solar power And plants that manage and control energy harvesting such as wind power, and plants that manage and control water and sewage and dams.

  As shown in FIG. 1, the wireless communication system A includes a wireless field device 1, a gateway device 2, a power supply device 3, an external power supply 4, and an external controller 5. The gateway device 2 and the power supply device 3 constitute the “wireless gateway system” of the present invention.

  The field wireless device 1 performs measurement, operation, and the like necessary for process control under the control of the external controller 5. Specifically, the field wireless device 1 captures, for example, a sensor device such as a flow meter or a temperature sensor, a valve device such as a flow control valve or an on-off valve, an actuator device such as a fan or a motor, a situation or an object in the plant Imaging devices such as cameras and video, acoustic devices such as microphones and speakers that collect abnormal sounds in the plant and emit alarm sounds, position detection devices that output position information of each device, and other devices .

The field wireless device 1 transmits and receives wireless signals by wireless communication with the gateway device 2. Here, the wireless signal is a control signal corresponding to a wireless communication protocol. For example, the wireless communication protocol is ISA100, WirelessHART (registered trademark), or the like.
For example, the field wireless device 1 performs a power saving operation (for example, an intermittent operation) using a battery as a power source, and can perform wireless communication with the gateway device 2 by the TDMA method based on the wireless communication standard ISA100.11a. The number of field wireless devices 1 that wirelessly communicate with the gateway device 2 is arbitrary.

The gateway device 2 is installed at, for example, a high place in order to obtain communication characteristics with the field wireless device 1. The gateway device 2 has a gateway function and wirelessly communicates with the wireless field device 1.
For example, the gateway device 2 installed in a high place and the power supply device 3 installed in a low place, for example, are connected via a cable CB. The gateway device 2 performs wired communication with the power supply device 3 via the cable CB. Here, the cable CB is a multi-core shielded cable having, for example, a power supply line, a signal line, and a ground line. The cable CB is preferably a cable capable of communication using differential signals (for example, half-duplex communication). As the cable CB, for example, a serial communication cable conforming to RS-485 can be used.

  Further, the gateway device 2 operates by the voltage (hereinafter referred to as “internal voltage”) supplied from the power supply device 3 via the cable CB, and can execute the gateway function. The schematic configuration of the gateway device 2 according to the first embodiment will be specifically described below.

  As shown in FIG. 1, the gateway device 2 includes an antenna 21, a gateway function unit 22, and a connector unit 23.

  The antenna 21 transmits and receives wireless signals to and from the wireless field device 1. Specifically, the antenna 21 transmits a radio signal from the gateway function unit 22, receives a radio signal transmitted from the wireless field device 1, and outputs the radio signal to the gateway function unit 22.

  The gateway function unit 22 operates using the internal voltage supplied from the power supply device 3 as a power source, and controls the control signal (wireless signal) corresponding to the wireless communication protocol received from the wireless field device 1 according to the wired communication protocol. The signal is converted into a signal (hereinafter referred to as a “wired signal”) and transmitted to the power supply device 3 via the connector unit 23 and the cable CB. The wired communication protocol is, for example, the Modbus (registered trademark) protocol, the HART (registered trademark) protocol, or the Foundation FieldBus (registered trademark) protocol.

  On the other hand, the gateway function unit 22 operates using the internal voltage supplied from the power supply device 3 as a power supply, converts the wired signal received from the power supply device 3 into a wireless signal, and outputs the wireless signal to the antenna 21.

  The connector unit 23 is a connection unit that connects the gateway device 2 to the cable CB, and is joined to the other end of the casing of the gateway device 2. Specifically, the gateway device 2 is fixed to the cable CB and electrically connected by screwing or fitting the connector portion 23 with an external connector (connector provided at one end of the cable CB). Connected.

The connector portion 23 includes a plurality of connection terminals 230 and 231.
The connection terminal 230 is a terminal that inputs and outputs wired signals transmitted and received between the gateway device 2 and the power supply device 3.
The connection terminal 231 is a terminal that receives internal voltage from the power supply device 3.
In addition, since it is conceivable that the gateway device 2 is installed outdoors, this connector portion 23 uses a connector that conforms to a waterproof and dustproof standard such as an IP (International Protection) standard or a NEMA (National Electrical Manufacturers Association) standard. Is desirable.

The power supply device 3 is installed in a low place in consideration of maintainability. The power supply device 3 includes connection terminals 31 and 32, a power supply circuit 33, and a connector unit 34.
The connection terminal 31 is electrically connected to the external controller 5 via the cable CD. The connection terminal 31 is a terminal for inputting / outputting a wired signal transmitted / received between the power supply device 3 and the external controller 5.

  The connection terminal 32 is electrically connected to the external power supply 4 via the cable CE. The connection terminal 32 is a terminal that receives an external voltage from the external power supply 4 via the cable CE.

  The power supply circuit 33 generates an internal voltage by converting the external power received at the connection terminal 32 into a predetermined voltage. The conversion to the predetermined voltage may be either step-up or high voltage, or may be rectified from alternating current to direct current. The predetermined voltage is a voltage at which the gateway device 2 can operate, and is a DC voltage of about several volts, for example.

  The connector portion 34 is a connection portion that connects the power supply device 3 to the cable CB, and is joined to the other end portion of the casing of the power supply device 3. Specifically, the gateway device 2 is fixed to the cable CB and electrically connected by screwing or fitting the connector portion 34 with an external connector (connector provided at the other end of the cable CB). Connected to.

The connector portion 34 includes a plurality of connection terminals 340 and 341.
The connection terminal 340 is electrically connected to the connection terminal 230. The connection terminal 340 is a terminal that inputs and outputs a wired signal transmitted and received between the gateway device 2 and the power supply device 3.

  The connection terminal 341 is a connection terminal that outputs the internal voltage converted by the power supply circuit 33 to the gateway device 2 and is electrically connected to the connection terminal 231.

  The external power supply 4 is installed in a low place, and supplies an external voltage to the power supply device 3 via the cable CE. For example, the external power source 4 may be a commercial power source that outputs AC 100V, or may be, for example, a power adapter that converts AC 100 from the commercial power source into DC 24V and outputs the DC 24V.

  The external controller 5 is installed in a low place, and transmits and receives a wired signal to and from the power supply device 3 via the cable CD. The external controller 5 collects various information of the wireless field device 1 by acquiring a wired signal, and controls the wireless field device 1 via the power supply device 3 and the gateway device 2 by transmitting the wired signal. I do. The external controller 5 is, for example, a distributed control system (DCS), a scatterer (SCADA: Supervisory Control And Data Acquisition), or a PLC (Programmable Logic Controller).

Below, operation | movement of the radio | wireless communications system A is demonstrated.
First, the case where the measured value measured by the field wireless device 1 is transmitted to the external controller 5 will be specifically described with reference to FIG.

  The external power supply 4 supplies an external voltage to the power supply device 3 via the cable CE (step S101). The external voltage supplied from the external power supply 4 is input to the connection terminal 32. The power supply circuit 33 generates an internal voltage by stepping down the external voltage input to the connection terminal 32 to a predetermined voltage. Then, the internal voltage generated by the power supply circuit 33 is output from the connection terminal 341 (step S102).

  The internal voltage output from the connection terminal 341 is input to the connection terminal 231 of the gateway device 2 installed at a high place via the cable CB. And the gateway apparatus 2 starts operation | movement with the internal voltage input into the connection terminal 231 (step S103). Here, since the gateway apparatus 2 does not include a power supply circuit, the size and weight are smaller than the conventional one. Therefore, when the gateway device 2 is installed at a high place, a relatively inexpensive fixing method can be employed. In addition, installation work can be performed with fewer workers. In this way, the gateway device 2 can be installed at a high place at a lower cost and with less work burden for installation.

  The field wireless device 1 performs measurement necessary for process control under the control of the external controller 5 (step S104). Then, the field wireless device 1 formats the measurement value into a wireless communication protocol and wirelessly transmits it to the gateway device 2 (step S105).

  The antenna 21 receives a wireless signal transmitted from the wireless field device 1, that is, a measurement value formatted in a wireless communication protocol, and outputs it to the gateway function unit 22.

  The gateway function unit 22 converts the format of the measurement value formatted in the wireless communication protocol received by the antenna 21 into the wired communication protocol (step S106). Then, the measurement value (wired signal) whose format is converted to the wired communication protocol by the gateway function unit 22 is output from the connection terminal 230.

  The wired signal output from the connection terminal 230 is input to the connection terminal 340 of the power supply device 3 installed in a low place via the cable CB. Here, since the cable that passes through the cable CB is an internal power supply and a digital signal, even if the cable CB is extended and the gateway device 2 is installed at a high place, the wired signal does not deteriorate. . Therefore, the cable CB can be extended and the antenna 21 can be installed at a high place without deteriorating the performance of wireless communication between the antenna 21 and the wireless field device 1.

  Since the connection terminal 340 and the connection terminal 31 are electrically connected, a wired signal input to the connection terminal 340 is transmitted to the connection terminal 31 and transmitted to the external controller 5 via the cable CD. That is, the power supply device 3 transmits the wired signal input to the connection terminal 340 to the external controller 5 (step S107). Then, the external controller 5 executes a preset operation based on the transmitted wired signal, that is, the measurement value converted into the wired communication protocol (step S108).

  Next, the operation when the wireless field device 1 is controlled using the wireless gateway system will be specifically described with reference to FIG. However, hereinafter, the gateway device 2 will be described by taking as an example a case where the operation has already been started by the internal voltage input to the connection terminal 231.

  The external controller 5 formats the control value of the wireless field device 1 into a wired communication protocol. Then, the external controller 5 transmits a control value (wired signal) formatted in the wired communication protocol to the power supply device 3 via the cable CD (step S201).

  A wired signal transmitted from the external controller 5 is input to the connection terminal 31. The wired signal input to the connection terminal 31 is transmitted to the connection terminal 340 and transmitted to the connection terminal 230 of the gateway device 2 via the cable CB. That is, the power supply device 3 transmits the wired signal input to the connection terminal 31 to the gateway device 2 (step S202).

  The gateway function unit 22 converts the format of the wired signal input to the connection terminal 230, that is, the control value formatted in the wired communication protocol, into the wireless communication protocol. Then, the control value (wireless signal) whose format is converted into the wireless communication protocol by the gateway function unit 22 is wirelessly transmitted to the wireless field device 1 by the antenna 21 (step S203).

  The field wireless device 1 receives a wireless signal from the antenna 21 and executes a predetermined operation based on the control value indicated by the received wireless signal (step S204).

  As described above, the wireless gateway system according to the first embodiment has a gateway function and is configured separately from the gateway device 2 including the antenna 21 that wirelessly communicates with the wireless field device, and the gateway device 2. Power supply device 3. The power supply device 3 converts the voltage from the external power supply 4 into a predetermined internal voltage, supplies the internal voltage to the gateway device 2, and transmits a wired signal between the external controller 5 and the gateway device 2. To do. On the other hand, the gateway device 2 operates using the internal voltage supplied from the power supply device 3 as a power source, converts the wireless signal received from the wireless field device 1 into a wired signal, and transmits the signal to the power supply device 3.

  Thus, since the gateway device 2 and the power supply device 3 are configured separately, the gateway device 2 can be reduced in size and weight. Therefore, the gateway device 2 can be easily installed at a high cost at a low cost.

  A cable CB wired between the gateway device 2 installed at a high place and the power supply device 3 installed at a low place passes a wired signal that is a digital signal instead of a high-frequency radio signal. Therefore, even if the cable CB is extended, the wired signal does not deteriorate. Therefore, the cable CB can be extended and the gateway device 2 can be installed at a high place without affecting the performance of wireless communication with the wireless field device 1.

(Second Embodiment)
FIG. 4 is a diagram illustrating an example of a schematic configuration of a wireless communication system B in which the wireless gateway system according to the second embodiment is used. In the drawings, the same or similar parts may be denoted by the same reference numerals and redundant description may be omitted.
The wireless gateway system according to the second embodiment includes an overcurrent protection circuit 35, a signal conversion unit 36, and an insulation circuit 37 in the power supply device 3 as compared with the first embodiment.

  As shown in FIG. 4, the wireless communication system B includes a wireless field device 1, a gateway device 2, a power supply device 3 </ b> B, an external power supply 4, and an external controller 5. The gateway device 2 and the power supply device 3B constitute the “wireless gateway system” of the present invention.

  The power supply device 3B is installed in a low place in consideration of maintainability. The power supply device 3B includes connection terminals 31 and 32, a power supply circuit 33, a connector unit 34, an overcurrent protection circuit 35, a signal conversion unit 36, and an insulation circuit 37.

  The overcurrent protection circuit 35 stops supplying the internal voltage when it detects that an overcurrent has flowed from the power supply circuit 33 to the cable CB. The cause of the overcurrent flowing in the cable CB is, for example, the case where the cable CB connected between the gateway device 2 installed in the high place and the power supply device 3 installed in the low place is not correctly wired. possible.

  The overcurrent protection circuit 35 is provided between the output of the power supply circuit 33 and the connection terminal 341. The overcurrent protection circuit 35 detects an overcurrent with respect to the gateway device 2 (or the cable CB) when a current output from the power supply circuit 33 exceeds a predetermined value. For example, when the overcurrent protection circuit 35 detects an overcurrent, the overcurrent protection circuit 35 stops the supply of the internal voltage by opening the electrical connection between the output of the power supply circuit 33 and the connection terminal 341.

  The signal conversion unit 36 is connected between the connection terminal 31 and the connection terminal 340. The signal conversion unit 36 converts the wired signal received from the gateway device 2 into a wired communication protocol (second wired communication protocol) different from the wired communication protocol (first wired communication protocol) converted by the gateway function unit 22. The data is converted and transmitted to the external controller 5. Here, for example, the Modbus (registered trademark) protocol or the HART (registered trademark) protocol can be adopted as the second wired communication protocol, as in the first wired communication protocol. The communication protocol is different from the protocol and is used by the external controller 5.

  The insulating circuit 37 is connected between the signal conversion unit 36 and the connection terminal 340. The insulation circuit 37 enables a wired signal to be transmitted bidirectionally while electrically insulating the gateway device 2 and the signal conversion unit 36 of the power supply device 3B. Thereby, the insulation circuit 37 can prevent noise from flowing from the external controller 5 to the gateway device 2. For example, the insulating circuit 37 is configured using an element such as a photocoupler.

  Hereinafter, an operation in a case where the measurement value measured by the wireless field device 1 according to the second embodiment is transmitted to the external controller 5 will be specifically described with reference to FIG. In the example described below, a case will be described in which the communication protocol used in the external controller 5 is the HART (registered trademark) protocol and the first wired communication protocol is the Modbus (registered trademark) protocol.

  The external power supply 4 supplies an external voltage to the power supply device 3B via the cable CE (step S301). The external voltage supplied from the external power supply 4 is input to the connection terminal 32. The power supply circuit 33 generates an internal voltage by stepping down the external voltage input to the connection terminal 32 to a predetermined voltage. The internal voltage generated by the power supply circuit 33 is output from the connection terminal 341 via the overcurrent protection circuit 35 (step S302). Here, when the current flowing through the overcurrent protection circuit 35 is equal to or greater than a predetermined value, the overcurrent protection circuit 35 opens the electrical connection between the output of the power supply circuit 33 and the connection terminal 341. Stop supplying internal voltage.

  The internal voltage output from the connection terminal 341 is input to the connection terminal 231 of the gateway device 2 installed at a high place via the cable CB. And the gateway apparatus 2 starts operation | movement with the internal voltage input into the connection terminal 231 (step S303).

  The field wireless device 1 performs measurement necessary for process control under the control of the external controller 5 (step S304). The wireless field device 1 then formats the measurement value into a wireless communication protocol and transmits it wirelessly to the gateway device 2 (step S305).

  The antenna 21 receives a wireless signal transmitted from the wireless field device 1, that is, a measurement value formatted in a wireless communication protocol, and outputs it to the gateway function unit 22.

  The gateway function unit 22 converts the measurement value formatted in the wireless communication protocol received by the antenna 21 into the first wired communication protocol (step S306). Then, the measurement value converted into the first wired communication protocol by the gateway function unit 22 is output from the connection terminal 230 and is input to the connection terminal 340 of the power supply device 3B installed in the low place via the cable CB. . Here, since the cable passing through the cable CB is a wired signal of an internal power source and a digital signal as in the first embodiment, even if the gateway device 2 is installed at a high place, this wired signal is Does not deteriorate. Therefore, the cable CB can be extended and the gateway device 2 can be installed at a high place without degrading the performance of wireless communication between the antenna 21 and the wireless field device 1.

  The measurement value based on the first wired communication protocol input to the connection terminal 340 is transmitted to the signal conversion unit 36 via the insulation circuit 37. The insulation circuit 37 signals the measurement value based on the first wired communication protocol input to the connection terminal 340 while electrically insulating the gateway device 2 and the signal conversion unit 36 of the power supply device 3B. The data is transmitted to the conversion unit 36.

  The signal conversion unit 36 converts the measurement value based on the first wired communication protocol into the second wired communication protocol, and transmits the converted value to the external controller 5 (step S307). Here, the second wired communication protocol is the HART (registered trademark) protocol, similar to the communication protocol used in the external controller 5. Therefore, when the first wired communication protocol and the communication protocol used by the external controller 5 are different, the measurement value formatted in the first wired communication protocol by the signal conversion unit 36 is used by the external controller 5. Is converted to a second wired communication protocol which is a communication protocol that has been used. Thereby, the wireless gateway system according to the second embodiment is measured by the wireless field device 1 even when the first wired communication protocol and the communication protocol used in the external controller 5 are different. The value can be transmitted to the external controller 5.

  The external controller 5 executes a preset operation based on the measurement value converted into the second wired communication protocol (step S308).

In addition, this invention is not limited to the said embodiment, For example, the following modifications can be considered.
(1) In the said embodiment, the gateway apparatus 2 may be provided with the power supply monitoring part which monitors an internal voltage. This power supply monitoring unit notifies the external controller 5 of an abnormality via the gateway device 2 when the internal voltage becomes a value outside the predetermined range. This abnormality notification is transmitted to the power supply device 3 via the cable CB. Then, the power supply device 3 transmits a notification of the abnormality to the external controller 5. Thereby, when the power supply circuit 33 cannot supply an internal voltage to the gateway apparatus 2 for some reason, the gateway apparatus 2 can notify the abnormality to the external controller 5 via the cable CB.

  (2) In the above embodiment, the gateway device 2 may be a module whose outer shape is a columnar shape or a polygonal column shape (for example, a rectangular column shape). In this case, the antenna 21 is disposed at one end of the casing of the gateway device 2 having a pillar shape. Here, one end of the casing of the gateway device 2 is an end opposite to the connector portion 23 provided at the other end of the casing of the gateway device 2.

  (3) In the above embodiment, the gateway device 2 may be filled with a resin so as to satisfy the intrinsically safe explosion-proof standard. That is, each component of the gateway function unit 22 accommodated in the housing of the gateway device 2 is sealed with the resin filled in the housing. Here, if the resin inside the casing causes an increase in cost and weight of the gateway device 2, only the surface layer of the gateway function unit 22 is filled without filling the resin inside the casing. May be partially filled so as to be coated with resin.

A wireless communication system 1 wireless field device 2 gateway device 3 power supply device 4 external power supply 5 external controller 21 antenna 22 gateway function unit 23 connector 31, 32 connection terminal 33 power supply circuit 35 overcurrent protection circuit 36 signal conversion unit 37 insulation circuit

Claims (6)

A wireless gateway system comprising a gateway device having a gateway function and having an antenna for wireless communication with a wireless field device, and a power supply device configured separately from the gateway device,
The power supply device
A voltage from an external power source is converted into a predetermined internal voltage, the internal voltage is supplied to the gateway device, and a wired signal corresponding to the first wired communication protocol is transmitted between the external controller and the gateway device. And
The gateway device operates using the internal voltage supplied from the power supply device as a power source, converts a wireless signal corresponding to a wireless communication protocol received from the wireless field device into the wired signal, and converts the wireless signal to the power supply device. Send,
A wireless gateway system. A cable for supplying an internal voltage is wired between the power supply device and the gateway device,
The wireless gateway system according to claim 1, wherein the power supply device further includes an overcurrent protection circuit that stops the supply of the internal voltage when it is detected that an overcurrent flows through the cable.   The wireless power supply according to claim 1, wherein the power supply device further includes an insulation circuit that allows the wired signal to be transmitted bidirectionally while electrically insulating the external controller and the gateway device. Gateway system.   The wireless gateway system according to any one of claims 1 to 3, wherein the gateway device converts the wired signal received from the power supply device into the wireless signal and transmits the wireless signal to the wireless field device.   The power supply device includes a signal conversion unit that converts the wired signal received from the gateway device into a second wired communication protocol different from the first wired communication protocol and transmits the second wired communication protocol to the external controller. The wireless gateway system according to any one of claims 1 to 4. A communication method of a wireless gateway system comprising a gateway device having a gateway function and wirelessly communicating with a wireless field device, and a power supply device configured separately from the gateway device,
Converting a voltage from an external power source into a predetermined internal voltage and supplying the internal voltage from the power supply device to the gateway device;
Converting a wireless signal corresponding to a wireless communication protocol received from the wireless field device into a wired signal corresponding to a first wired communication protocol and transmitting the signal from the gateway device to the power supply device;
Transmitting the wired signal transmitted from the gateway device to the power supply device toward an external controller;
A communication method for a wireless gateway system, comprising:

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